PL196714B1 - Method for operating a refuse incineration plant - Google Patents

Abstract

The invention relates to a method for operating a refuse incineration plant and to a regulating system, in which, after the fire has been fanned, the generation of heat is made more uniform by regulating at least one of the operating parameters refuse metering, residence time on a grate, quantitative supply of primary air and quantitative preheating of primary air. To match the operating parameters to a varying calorific value of the refuse, the calorific value of the refuse is recorded as well as the standard regulating variables and is used to adapt the regulating means. The measure used for the calorific value is, for example, the moisture content of the flue gas generated during the incineration. Consequently, there is no need for the operator to estimate the calorific value and manually adapt the operating parameters accordingly.

Description

(12) PATENT DESCRIPTION (19) PL (11) 196714 (21) Filing number: 355634 ^{(13) B1} (22) Filing date: October 24, ^{2001 (51) Int.Cl.}

F23G 5/50 (2006.01) (86) Date and number of the international application:

2001-10-24, PCT / CH01 / 00630 (87) International application publication date and number:

June 13, 2002, WO02 / 46661 PCT Gazette No. 24/02 (54)

Waste incineration method and waste incineration device

(30) Priority: 2000-12-08, CH, 20002398/00 (73) The right holder of the patent: VON ROLL UMWELTTECHNIK AG, Zurich, CH (43) Application was announced: 04.05.2004 BUP 09/04 (72) Inventor (s): Alfons Schirmer, Z ^ them, CH Josef Mercx, Baden, CH (45) The grant of the patent was announced: (74) Representative: Borowska-Kryśka Urszula, PATPOL Sp. z o.o. 31.01.2008 WUP 01/08

(57) 1.Waste incineration method in which, after lighting the fire, the heat generation is uniform, using at least one regulator, by regulating a large number of operating parameters, including at least one of the operating parameters such as waste supply, time spent on the grate and supply of air the first, as a function of a plurality of measurands, including at least one of the measured values of the oxygen content in the exhaust gas and the amount of steam produced, characterized in that a calorific value parameter (228) is generated from the other measurand, which is a measure of the calorific value waste or its changes, and at least one of the operating parameters is also set depending on the calorific value parameter (228), .......................... ...........................

8.Waste incineration appliance with a combustion chamber including a grate, a boiler and a control system for regulating at least one of the operating parameters of a waste incineration appliance comprising at least one regulator for regulating at least one of the actuating members of the pusher, grate, primary air flaps or quantity pre-heater the first air, characterized in that the control system has a measuring device (107, 108, 217) for determining the measured quantity from which the calorific value parameter (228) is determined, ............... .......................................

PL 196 714 B1

Description of the invention

The present invention relates to a waste incineration method and a waste incineration device.

There is known a method of incineration of waste, in which, after lighting the fire, the heat production is uniform, using at least one regulator, by adjusting a large number of operating parameters, including at least one of the operating parameters such as waste feed, residence time on the grate and primary air supply, in depending on a plurality of measurands including at least one measurand of exhaust gas oxygen content and amount of steam produced.

There is also known a waste incineration device with a combustion chamber including a grate, a boiler and a control system for adjusting at least one of the operating parameters of the waste incineration device, including at least one controller for adjusting at least one of the actuating members of the pusher, grate, primary or pre-air flaps. first air quantity heater.

Operation, and especially the uniform heat generation in oil or coal-fired power plants, poses no problems. This is achieved by uniformly dosing the amount of fuel, the quality of which is constant and known. Also in waste incineration plants the main goal is to keep the thermal power constant. In addition, the exhaust gas must comply with legally defined quality and quantity regulations. The heat power cannot be controlled only by dosing the supplied waste, since the calorific value of waste, depending on its different composition and variable water content, can vary considerably. For this reason, keeping the amount of heat constant is difficult at present. Even more problematic is the additional optimization of the remaining parameters.

EP-B-0 499 976 discloses a method of operating a waste incineration device, in which, in order to homogenize the amount of heat generated, the waste is supplied, i.e. the movement of the dosing pusher, the waste is transported on the grate, i.e. the relative movement, the frequency of the grate part's movement. and the supply of first air is regulated by the cascade control. The amount of steam produced is determined with a delay and serves as the main controlled quantity. As an auxiliary control variable, a rapidly achievable oxygen content value in the exhaust gas is used. By means of this flame capacity control, the waste incinerator can be largely automatically adapted to the slightly changing properties of the waste and thus to small fluctuations in calorific value. However, the frequency of the feed of the grate, the movement of the pusher and the supply of the first air always go in the same direction, i.e. they are increased or decreased. Larger changes in the waste feed or the calorific value, which require the operating parameters to be changed in opposite directions, are not sufficiently compensated by this flame efficiency control. This is the case, for example, in the transition to wet, highly compacted waste, where the pusher speed should be reduced to reduce the waste feed and the frequency of the grate movement should be increased to separate and break up the waste. In the known methods, fluctuations in calorific value are then compensated in the short term by fueling or inhibiting the intensity of the flame, and in the longer term by increasing the amount of waste. The automatic regulation of the flame efficiency does not take into account the correct course of combustion along the length of the grate.

In practice, such changes in calorific value are usually compensated by the operator who assesses the waste feed or the position of the flame on the basis of visual observation. The operator then adjusts the individual operating parameters manually, for example frequently increasing the preheating of the primary air when the waste is wet. The disadvantage here is that the adjustment of the operating parameters is complicated and not always optimally selected due to the various possibilities of intervention and interactions. It largely depends on the experience of the staff. The regulation has a very long delay here, so that the full effectiveness of the intervention can only be assessed after about an hour.

EP-A-1046861 discloses a method for automatically adjusting incineration in a waste incineration plant, in which the calorific value of the waste is continuously determined from the actual heat generated in the incineration space and the registered mass flow rate of the waste.

PL 196 714 B1

The object of the invention is therefore to simplify the operation of a waste incineration device, in particular to develop a waste incineration method in which the adjustment of the operating parameters to the changing properties of the waste, in particular fluctuations in the calorific value, is largely automatic.

A waste incineration method in which, after the fire has been ignited, the heat generation is homogenized by using at least one regulator by regulating a large number of operating parameters, including at least one of the operating parameters such as waste feed, grate residence time and primary air supply, depending on a number of parameters. measured values, including at least one of the measured values in the form of oxygen content in flue gases and the amount of steam produced, according to the invention, it is characterized by the fact that a calorific value parameter is generated from another measured value, which is a measure of the calorific value of waste or its change and at least one of the operating parameters is also set as a function of the calorific value parameter, wherein at least one correction value is assigned to the calorific value parameter or is assigned in accordance with a predetermined recipe by means of which the at least one input variable and / or at least one output variable and / or at least one controller gain of at least one controller.

Preferably, in the method according to the invention, at least two, preferably all of the following operating parameters are set depending on the calorific value parameter, the sum of the first air and the secondary air, the ratio of the first air to the secondary air, the position of the zone flaps, the amount of the first air, the amount of waste supplied, time stay on the grate, required oxygen value, primary air preheating.

The calorific value parameter is determined from the humidity of the flue gas produced during combustion.

The calorific value parameter is determined from the temperature of the flue gas produced during combustion and then saturated with water vapor.

In the method according to the invention, for setting the operating parameter, the sum is used which results from the output quantity of the controller, from a correction quantity generated from the calorific value parameter, and preferably from a predetermined basic setting value.

The input quantity of the controller is modified with a correction quantity.

In the method according to the invention, for adjusting the operating parameters in the form of the waste feed, the residence time on the grate, the feed of the primary air and the pre-heating of the primary air, setting values are used that come from at least the measured values for the oxygen content in the flue gas and the amount of steam produced, and which it is modified depending on the calorific value parameter.

Waste incineration device with a combustion chamber including a grate, a boiler and a control system for adjusting at least one of the operating parameters of a waste incineration device comprising at least one controller for controlling at least one of the actuating members of the pusher, grate, primary air flaps or primary air preheater , according to the invention, is characterized in that the control system has a measuring device for determining the measured quantity, from which the calorific value parameter is determined, which is a measure of the calorific value of the waste or its change, and furthermore, the control system has a calorific value correction unit, which generates a calorific value on the basis of the calorific value parameter. at least one corrective quantity modifying the at least one input quantity and / or one output quantity and / or the gain of the controller of at least one controller.

The measuring device is a device for measuring flue gas humidity or water-saturated flue gas temperature.

Preferably, in the device according to the invention, the calorific value correction unit has a switch for assigning a plurality of correction quantities to the calorific value parameter, preferably a processor, with which the correction quantities are calculated from the calorific value parameter.

The apparatus of the invention comprises measuring devices for the amount of steam and for the oxygen content of the flue gas.

Advantageously, the device according to the invention has a multi-circuit control device with a main controller with a supplied basic control variable obtained from the measured quantity of steam and with at least three faster auxiliary controllers connected to the main controller, with an auxiliary control supplied from the measured oxygen content and the outputs of which are connected in each case. they are with one of the regulators.

PL 196 714 B1

The device according to the invention has a measuring device which is a device for measuring the temperature of the flue gas saturated with water vapor, which is situated downstream of the water injection device.

When operating a waste incineration device, after lighting the fire, the heat generation is uniformly evened out (flame efficiency control) by regulating many operating parameters, such as the waste feed, the residence time on the grate and the primary air supply, depending on a number of values. measured values, or at least one of such measurement variables as the oxygen content of the exhaust gas and the amount of vapor produced.

According to the invention, a calorific value parameter is formed from the measured value, which is a measure of the calorific value of the added waste or its change. When changing known control techniques, at least one of the operating parameters is also set at least as a function of the calorific value parameter.

The calorific value or its change are found automatically by analyzing the relevant measured values. According to a predetermined scheme, for example empirically or by model calculus, the calorific value parameter is influenced to control at least one operating parameter. Ideally, there is no need for any manual intervention as it occurs automatically according to objective criteria and the device can in principle be left on its own.

In addition, the possibility of manual intervention may also be provided. The calorific value or its change is hereby evaluated by the operator, for example by observing the position of the flame. By means of the process control, a quantity is entered manually in the form of a calorific value parameter, which, for example, determines how far the estimated calorific value deviates from the nominal calorific value adopted for determining the dimensions of the furnace.

The measured value for the calorific value parameter is determined automatically. In a preferred embodiment of the method, the moisture content of the exhaust gases is used as a measure of the calorific value. The initial assumption is that the calorific value of waste significantly depends on the water it contains. As the water contained in the waste immediately begins to evaporate after it is fed to the furnace, the measured humidity, without a long delay, gives changes in the composition of the waste. A suitable signal is then available for directly adapting the operating parameters or their control to the changed calorific value. The flue gas humidity can be measured directly with the humidity sensor. Preferably, the flue gas is saturated with water and the readily measurable temperature of the saturated flue gas is used as a measure of the moisture content and thus the calorific value. Evaporative heat dissipation is greater when there was less water in the flue gas at the beginning. The temperature of the water-enriched flue gas is thus a measure of the prior water content of the waste, and therefore is a measure of the calorific value. Since many waste incineration plants have a water injection and scrubber, this variant is particularly easy to implement. Preferably the temperature is measured after the water injection, in the sludge of the scrubber or at the exit of the scrubber.

From the calorific value parameter, at least one correction variable is automatically determined which modifies at least one of the setting values for the regulation of the flame efficiency and / or one of the variables used for the regulation of the flame efficiency, for example the inputs or gains of the regulators involved in the process. A large number of operating parameters are thus advantageously influenced so that by intervention or on the basis of the automatically determined calorific value, the characteristic curve of the entire device can be shifted and optimally adapted to the changed calorific value. Correction quantities are established, for example, on the basis of model calculus or based on empirical values.

By means of the correction variable, for example, the setting area or the operating point of an individual controller is shifted, while the control of the output and the heat output remains constant in the known manner.

In a further advantageous embodiment of the invention, the control gain of the at least one controller is modified by means of the correction quantity derived from the calorific value parameter. As a result, the operating range of this controller is adapted to the changed calorific value. Furthermore, the setting value and / or the desired value of this controller or other controllers can also be adapted by means of suitable correction quantities derived from the same calorific value parameter.

PL 196 714 B1

Depending on the calorific value parameter, the following operating parameters are preferably set: the sum of the primary air and secondary air, the ratio of primary air to secondary air, setting of zone flaps, primary air, additional waste supply, time spent on the grate, required oxygen value, initial primary air heating.

The control system according to the invention for regulating at least one of the operating parameters of a waste incineration device comprises at least one controller which, on the basis of the at least one control variable supplied as an input signal and / or at least one desired value, produces an output signal which is supplied as a value. setting to one of the actuating members for the follower, grate, primary air flaps, or primary air preheater. According to the invention, there is a first measuring device for determining a measured quantity from which a measured value parameter is derived, which is a measure for the calorific value of the waste or for its change. Furthermore, there is a calorific value correction unit which, on the basis of the calorific value parameter, produces a correction quantity with which at least a set point value and / or a setting value and / or a regulator gain are modified for at least one regulator.

A waste incinerator with such a control system has all the advantages of the control system. The control system serves in particular to carry out the method according to the invention.

The subject of the invention is shown in the embodiment in the drawing, in which Fig. 1 - shows a synoptic diagram of a waste incineration device, Fig. 2 - an example of regulation according to the invention, Fig. 3a - examples of the characteristics of the follower regulator for a grate, at different calorific values, Fig. 3b - examples of the characteristics of a follow-up regulator for supplying air at different calorific values, and fig. 4 - shows an example of a regulator system for a follow-up regulator.

Figure 1 shows a mimic diagram of a waste incineration plant. The waste is supplied to the combustion chamber 101 by means of a pusher not shown. The supplied waste is fed to a powered combustion grate, not shown here, where the waste is dried, degassed and incinerated. The combustion process depends on the supply of primary air, secondary air and the movement of the grate. The hot exhaust gases 102 from the combustion chamber 101 are passed to a boiler, not shown here, where they are used to generate steam. The exhaust gas then passes through a water injection device or cooling device 103, in which the exhaust gas 102 is saturated with water 104. The water-saturated exhaust gas 105 is then fed to the exhaust gas purification station 106.

The temperature measuring device 108 measures the temperature of the flue gas 105 saturated with water. The measured value is supplied to a processing unit 109, which generates a parameter of the calorific value 110. The processing unit 109 includes, for example, a controller PJ. For example, the instantaneous temperature deviation from the continuous mean temperature value is a measure of calorific value or calorific value deviation. The flue gas temperature used for the control is measured downstream of the cooling device 103, in the sludge of the scrubber 106 or in the area of the scrubber exit.

For the determination of the calorific value parameter 110, it is also possible to measure the humidity of the unsaturated flue gas 102 by using a humidity measuring device 107, the result of which is evaluated in a processing unit 109, this is particularly applicable in installations without a cooling device 103.

The control system shown in Fig. 2 has known measuring devices 201, 202 for the oxygen content in the exhaust gas and for determining the amount of steam. The operating parameters in the form of waste feed are regulated, by influencing the pusher actuator 209 and the residence time on the grate, by influencing the grate actuating member 210, and preheating the first air, by influencing the corresponding actuating member 208 and further parameters relating to the primary air supply. and recycling and decomposing them by acting on the functional unit air 211, which may include further regulators. By means of the functional unit, the air 211 acts on the actuating members, not shown here, for the total air quantity, the primary air quantity, the secondary air quantity and the air supply to the individual grate zones. The measured value of the amount of steam 222 as an input is supplied to the main or lead controller 203. This controller is preferably a slow controller PJ. Its output signal 223 is applied

The desired value of the auxiliary controllers 204, 205, 206 is represented by the output 223 of the main controller 203 based on the measured values of the amount of steam. . The measured value for the oxygen content 224 is applied as an additional input to the slave controllers 204, 205, 206. The setpoint desired value for the oxygen content 213 serves as the third input for all three slave controllers 204, 205, 206. Outputs of the slave controllers 204, 205, 206 are connected to the follower, grate and air setting members 209, 210, 211.

By means of the control unit 214, the basic setting of the actuating members 209, 210, 211 is determined based on the desired desired value for pair 212. Corresponding signals, as basic setting values 226, are applied to the setting members 209, 210, 211. These basic values are the set points are modified by the outputs of the auxiliary controllers 204, 205, 206 which, for example, are added to the primary set values 226.

According to the invention, the so far described known control system has been developed with the possibility of automatic adaptation to changing calorific values. For this purpose, a measuring device 217 is provided for the measurand from which a measure of the calorific value or its change can be obtained, for example the temperature of the water-saturated flue gas. From this measured quantity, the calorific value parameter 228 is generated in the unit 216 and fed as an input quantity to the calorific value correction unit 215. From the calorific value parameter, it determines a plurality of correction variables 218, 219, 220, 221 with which the control of the operating parameters is modified. First, the calorific value correction unit 215 produces a correction quantity 218 for the desired oxygen content value by which the oxygen demand value 213 supplied to the auxiliary controllers as input 225 is matched to the changed calorific value, e.g. the desired value. By means of the correction variables 219 for the setting values, the setting value 227 supplied to the setting members 209, 210, 211 is modified. For example, the setting value is a sum consisting of the output signal of the auxiliary regulators 204, 205, 206 and the corresponding basic setting value. 226 and with the appropriate correction value. Optimal adaptation of the operating parameters to the current calorific value is achieved by appropriately determining the correction quantities for the individual actuators with only one, automatically running intervention. For example, when switching to a wet, highly compacted waste (with a lower calorific value), the pusher speed is reduced (negative correction value for actuator 209 to follower) and increased frequency of the grate travel (positive correction value for actuator 210 to grate).

In a preferred embodiment of the invention, the calorific value correction unit 215 produces additional correction quantities 220 with which the gain of the auxiliary regulators 204, 205, 206 is modified. For example, at high calorific values, the gain of the auxiliary regulator 205 regulating the actuator is increased. 210 for the grate and the gain of the auxiliary regulator 206 regulating the functional unit 211 for air is reduced. At the same time, the basic setting values are adapted by means of correction variables 219. This is based on the recognition that different calorific values of waste require different regulatory responses (reinforcements). In addition, the waste incineration process on the grate depends on the calorific value and therefore requires measures that, for each waste feed, ensure optimal coverage of, inter alia, the grate (adjustment of the basic setting values). For example, at high calorific values, the device works primarily on the basis of the work of the grate, i.e. with short residence times on the grate, and at low calorific values, taking into account primarily air. Such methods of operation can be carried out according to the invention by modifying the gain of the regulator.

The calorific value correction unit 215 produces an additional control quantity 221 which serves directly as a setting value for the actuating member 208 for preheating the first air.

3a and 3b each show two examples of the characteristics of a follow-up regulator for the grate or for the air supply or the setting values of the respective actuators at high calorific values (broken line) and low calorific values (dotted line). Fig. 3a shows the frequency of the grid advance fR,

As a function of the measured oxygen content or the control deviation of the follow controller. The control value X1, X2, with a control deviation equal to zero, is determined by a basic amount that has been determined by the control unit 214 and corrected based on the detected calorific value. The basic setting X1 for a high calorific value is therefore smaller than the basic setting X2 for a lower calorific value. The slope of the characteristic curve is determined by the gain of the controller, which is higher at high calorific value than at lower one. In the case of the first air supply PL, the control of which is shown in Fig. 3b, the basic settings X1, X2 and the regulator gain are lower at high calorific value than at lower calorific value.

FIG. 4 shows an example of a regulator circuit for the following regulator 205 or 206 of FIG. 2. From the calorific value parameter 228, the correction variables 218, 219, 220 are generated in the calorific value correction unit 215. 4, symbolized by the nonlinear curves in the correction unit 215. The desired oxygen value 213 together with the output 223 from the steam regulator, which determines the offset of the desired oxygen value and with the correction value of the desired value 218, are fed to the summing factor. The difference from the actual measured oxygen value 224 is amplified or attenuated, with the proportionality factor being determined by the gain correction amount of the controller 220. To this amount, the amount of the basic setting value 226 of the output variable 227 and the correction amount 219 of the setting value are added. The primary setting value 226 of the output variable 227 is generated in the control unit 214 by multiplication and addition with predetermined amounts from the predetermined desired value of the pair 212. The setting member 209 or 210 is actuated by the output variable 227 thus produced.

Claims (13)

Patent claims A method of waste incineration, in which, after lighting the fire, the heat generation is homogeneous, using at least one regulator, by adjusting a large number of operating parameters, including at least one of the operating parameters such as waste feed, residence time on the grate and primary air supply, in depending on a plurality of measured quantities, including at least one measured quantity in the form of the oxygen content in the flue gas and the amount of steam produced, characterized in that a calorific value parameter (228) is generated from another measured quantity, which is a measure of the calorific value of the waste or its changes, or at least one of the operating parameters, are also set depending on the calorific value parameter (228), where the calorific value parameter (228) is assigned at least one correction quantity or is assigned in accordance with a predetermined recipe, by means of which it is modified come on at least one input quantity (225) and / or at least one output quantity (227) and / or at least one controller gain of at least one controller (204, 205, 206). 2. The method according to p. A method according to claim 1, characterized in that at least two, preferably all of the following operating parameters are set depending on the capacity of the calorific value parameter (228), the sum of the first air and the secondary air, the ratio of the first air to the secondary air, the position of the zone flaps, the amount of primary air, amount of waste supplied, residence time on the grate, required oxygen value, primary air heating. 3. The method according to p. The method of claim 1 or 2, characterized in that the calorific value parameter (228) is determined from the humidity of the flue gas (102) produced during combustion. 4. The method according to p. The method of claim 1 or 2, characterized in that the calorific value parameter (228) is determined from the temperature of the flue gas (104) produced during combustion and then saturated with water vapor. 5. The method according to p. A method as claimed in claim 1, characterized in that for setting the operating parameter the sum of the controller output quantity (204, 205, 206), the correction quantity (219) generated from the calorific value parameter (228) and preferably the predetermined basic setting value ( 226). 6. The method according to p. The method of claim 1 or 5, characterized in that the input quantity (225) of the regulator (204, 205, 206) is modified with a corrective quantity (218). PL 196 714 B1 7. The method according to claim The method as claimed in claim 1 or 2, characterized in that for the adjustment of the operating parameters in the form of waste feed, residence time on the grate, primary air supply and primary air preheating, setting values are used which come at least from the measured values relating to the oxygen content (224) in the grate. flue gas and the amount of steam produced (222) and which is modified depending on the calorific value parameter (228). 8.Waste incineration appliance with a combustion chamber containing a grate, a boiler and a control system for regulating at least one of the operational parameters of a waste incineration appliance comprising at least one regulator for regulating at least one of the actuating members of the pusher, grate, primary air flaps or pre-heater first air quantity, characterized in that the control system has a measuring device (107, 108, 217) for determining the measured quantity, from which the calorific value parameter (228) is determined, which is a measure of the calorific value of waste or its change, and furthermore the control system has a unit a corrective calorific value (215) that produces from the calorific value parameter (228) at least one corrective quantity (218, 219, 220, 221) modifying at least one input quantity (225) and / or one output quantity (227) and / or regulator gain of at least one regulator (203, 204, 205, 2 06). 9. Device according to claim The apparatus of claim 8, characterized in that the measuring device (107, 108, 217) is a device for measuring the flue gas humidity (102) or the water-saturated flue gas temperature (104). 10. The device according to claim 1 The calorific value correcting unit (215) comprises a switch for assigning the calorific value parameter (228) a plurality of correction quantities (218, 219, 220, 221), preferably a processor, by means of which the correction quantities (218, 219, 220, 221) are calculated from the calorific value parameter (228). 11. The device according to claim 1 Device according to claim 8 or 9, characterized in that it comprises measuring devices for the amount of steam and for the oxygen content (202, 201) in the exhaust gas. 12. The device according to claim 1, A control device according to claim 8, characterized in that it has a multi-circuit control device with a main controller (203) with an applied basic control variable obtained from the measured amount of steam (222) and with at least three faster auxiliary controllers (204, 205, 206 connected to the main controller (203). ), with an input control variable from the measured oxygen content (224), and the outputs of which are each connected to one of the actuators (209, 210, 211). 13. The device according to claim 1, Device according to claim 8, characterized in that the device has a measuring device (108) which is a device for measuring the temperature of the flue gas (105) saturated with water vapor, which is located downstream of the water injection device (103).